Fast mode transitions in a power converter

ABSTRACT

Disclosed embodiments of a power converter include a power output stage for generating a first voltage output and an auxiliary power output stage for generating a second voltage output. The power converter further includes a pulse frequency modulation (PFM) controller for controlling the power output stage in response to the first voltage output generated by the power output stage during a first period of time in which the power output stage operates in a PFM mode, and a pulse width modulation (PWM) controller for controlling the auxiliary power output stage in response to the second voltage output generated by the auxiliary power output stage during a second period of time. At least a portion of the first period of time is concurrent with the second period of time.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application is a continuation of U.S. patent applicationSer. No. 16/118,759, filed on Aug. 31, 2018, which is a continuation ofU.S. patent application Ser. No. 15/597,400, filed on May 17, 2017, nowU.S. Pat. No. 10,069,419, which is a continuation of U.S. patentapplication Ser. No. 14/588,111, filed on Dec. 31, 2014, now U.S. Pat.No. 9,685,863, each of which is incorporated by reference herein in itsentirety.

BACKGROUND

Many communication systems, which often include wireless devices thatboth transmit and receive, operate in accordance with data transmissionstandards. Often, the data transmission standards specify relativelystrict spectral mask requirements, which specify reduced amounts ofnoise, such as electromagnetic interference (EMI), during datatransmission. The transmitter of such communication devices includes apower amplifier (PA) that is operable to transmit data in accordancewith a data transmission standard. The PA typically receives power froma power converter, such as a DC-DC (direct current-to-direct current)converter. The power converter typically operates in a pulse-widthmodulation (PWM) mode during transmission in order to increase EMIcompliance. The operating load on the power converter typically variesduring operation of the communication device. For example, the operatingload typically is relatively low while the system is in receive mode,during which time of operation the PA (and the power converter) isoptionally turned off to conserve power. The power converter can beturned off because is normally inefficient to operate the powerconverter in a PWM mode during such times of low operating loads.

However, turning the power converter on again entails a relatively longwakeup time (e.g., on the order of hundreds of microseconds) duringwhich the transmitter is not available for transmitting. The powerconverter can be switched to run in a relatively more efficientpulse-frequency modulation (PFM) mode during such low-load periods, butduring the transition back to a PWM mode for a higher-load transmissionperiod typically requires a settling time on the order of a few tens ofmicroseconds. Such settling times exceed the settling requirements ofsome applications.

SUMMARY

The problems noted above can be solved in a fast mode-transitioningpower converter. For example, the disclosed power converter includes aPFM controller, a PWM controller, and an auxiliary voltage output stage.The PFM controller controls a power output stage in a PFM mode inresponse to a power stage voltage output generated by the power outputstage during a first period of time in which the power output stage isoperating in the PFM mode. The PWM controller controls the power outputstage in a PWM mode in response to a power stage voltage outputgenerated by the power output stage during a second period of time inwhich the power output stage is operating in the PWM mode. The auxiliaryvoltage output stage generates an auxiliary voltage during a thirdperiod of time, where the PWM controller controls the auxiliary voltageduring the third period of time.

This Summary is submitted with the understanding that it is not be usedto interpret or limit the scope or meaning of the claims. Further, theSummary is not intended to identify key features or essential featuresof the claimed subject matter, nor is it intended to be used as an aidin determining the scope of the claimed subject matter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an illustrative electronic device in accordance withexample embodiments of the disclosure.

FIG. 2 is a schematic diagram illustrating a fast mode-transitioningpower converter in accordance with example embodiments of thedisclosure.

FIG. 3 is a waveform diagram illustrating switching waveforms and outputvoltages of a fast mode-transitioning power converter in accordance withexample embodiments of the disclosure.

FIG. 4 is a waveform simulation illustrating switching waveforms, outputvoltages, and currents of a fast mode-transitioning power converter inaccordance with example embodiments of the disclosure.

FIG. 5 is a flow diagram of the operation of a fast mode-transitioningpower converter in accordance with example embodiments of thedisclosure.

DETAILED DESCRIPTION

The following discussion is directed to various embodiments of theinvention. Although one or more of these embodiments may be preferred,the embodiments disclosed should not be interpreted, or otherwise used,as limiting the scope of the disclosure, including the claims. Inaddition, one skilled in the art will understand that the followingdescription has broad application, and the discussion of any embodimentis meant only to be example of that embodiment, and not intended tointimate that the scope of the disclosure, including the claims, islimited to that embodiment.

Certain terms are used throughout the following description—andclaims—to refer to particular system components. As one skilled in theart will appreciate, various names may be used to refer to a componentor system. Accordingly, distinctions are not necessarily made hereinbetween components that differ in name but not function. Further, asystem can be a sub-system of yet another system. In the followingdiscussion and in the claims, the terms “including” and “comprising” areused in an open-ended fashion, and accordingly are to be interpreted tomean “including, but not limited to . . . .” Also, the terms “coupledto” or “couples with” (and the like) are intended to describe either anindirect or direct electrical connection. Thus, if a first devicecouples to a second device, that connection can be made through a directelectrical connection, or through an indirect electrical connection viaother devices and connections. The term “portion” can mean an entireportion or a portion that is less than the entire portion. The term“calibration” can include the meaning of the word “test.” The term“input” can mean either a source or a drain (or even a control inputsuch as a gate where context indicates) of a PMOS (positive-type metaloxide semiconductor) or NMOS (negative-type metal oxide semiconductor)transistor. The term “pulse” can mean a portion of waveforms such as“squarewave” or “sawtooth” waveforms.

FIG. 1 shows an illustrative computing device 100 in accordance withembodiments of the disclosure. For example, the computing device 100 is,or is incorporated into, or is coupled (e.g. connected) to an electronicsystem 129, such as a computer, electronics control “box” or display,communications equipment (including transmitters or receivers), or anytype of electronic system operable to process information. In variousembodiments, the electronics system 129 is included in atelecommunications system (or a portion thereof such as atransmitter-receiver or transceiver), and in more particularembodiments, a wireless and/or low-power transceiver.

In various embodiments, the computing device 100 comprises a megacell ora system-on-chip (SoC) which includes control logic such as a CPU 112(Central Processing Unit), a storage 114 (e.g., random access memory(RAM)) and a power supply 110. The CPU 112 can be, for example, aCISC-type (Complex Instruction Set Computer) CPU, RISC-type CPU (ReducedInstruction Set Computer), MCU-type (Microcontroller Unit), or a digitalsignal processor (DSP). The storage 114 (which can be memory such ason-processor cache, off-processor cache, RAM, flash memory, or diskstorage) stores one or more software applications 130 (e.g., embeddedapplications) that, when executed by the CPU 112, perform any suitablefunction associated with the computing device 100.

The CPU 112 comprises memory and logic that store information frequentlyaccessed from the storage 114. The computing device 100 is oftencontrolled by a user using a UI (user interface) 116, which providesoutput to and receives input from the user during the execution of thesoftware application 130. The output is provided using the display 118,indicator lights, a speaker, vibrations, and the like. The input isreceived using audio and/or video inputs (using, for example, voice orimage recognition), and electrical and/or mechanical devices such askeypads, switches, proximity detectors, gyros, accelerometers, and thelike.

The CPU 112 and power supply 110 are coupled to I/O (Input-Output) port128, which provides an interface that is configured to receive inputfrom (and/or provide output to) networked devices 131. The CPU 112 andpower supply 110 are also coupled to the power amplifier (PA) 125, whichprovides power to the electronic system 129. Although the PA 125 isillustrated as being included in the I/O port 128, in variousembodiments the PA 125 is optionally physically separated from the I/Oport 128. The networked devices 131 can include any device (includingtest equipment) capable of point-to-point and/or networkedcommunications with the computing device 100. The computing device 100is often coupled to peripherals and/or computing devices, includingtangible, non-transitory media (such as flash memory) and/or cabled orwireless media. These and other input and output devices are selectivelycoupled to the computing device 100 by external devices using wirelessor cabled connections. The storage 114 is accessible, for example, bythe networked devices 131. The CPU 112, storage 114, and power supply110 are also optionally coupled to an external power supply (not shown),which is configured to receive power from a power source (such as abattery, solar cell, “live” power cord, inductive field, fuel cell,capacitor, and the like).

The power supply 110 comprises power generating and control componentsfor generating power to enable the computing device 100 to execute thesoftware application 130. For example, the power supply 110 provides oneor more power switches, each of which can be independently controlled,that supply power at various voltages to various components of thecomputing device 100. The power supply 110 is optionally in the samephysical assembly as computing device 100, or is coupled to computingdevice 100. The computing device 100 optionally operates in variouspower-saving modes wherein individual voltages are supplied (and/orturned off) in accordance with a selected power-saving mode and thevarious components arranged within a specific power domain.

The power supply 110 is in various embodiments a switched-mode powersupply (e.g., “converter”) that alternately stores and outputs energy.Such converters typically receive either a DC (direct current) orrectified AC (alternating current) voltage as an input voltage. Energyderived from the input voltage is temporarily stored in energy storagedevices (such as inductors and capacitors) during each switching cycle.A power switch in the converter is actuated (e.g., closed for a “turnedon” state or opened for a “turned off” state) to control the amount ofenergy that is output. A filter is normally used to reduce ripple in theoutput DC voltage and current. Depending on the topology selected forthe converter, the output DC voltage can be higher or lower than theinput voltages. The output DC voltage can also be inverted with respectto the input voltage.

Switching converters typically operate in either a discontinuous mode ora continuous mode. In the discontinuous mode, converters completelyde-energize the energy storage devices before the end of every switchingcycle. Accordingly, no current flows in the energy storage devices atthe start of every switching cycle in the discontinuous mode. In thecontinuous mode, converters normally do not completely de-energize theenergy storage devices before the end of every switching cycle.Accordingly, the current in the energy storage devices operating in acontinuous mode normally does not reach a point where current does notflow in the energy storage devices.

The discontinuous inductor current conduction mode (DCM) is a power modethat is used to improve light-load efficiency in switching powerconverters. Because many computing devices 100 typically operate inapplications that present electrical loads that are in thelight-to-medium load current range, the light-load efficiency of voltageregulators has a substantial impact of the power efficiency of a system.

The output of a converter is determined in part by the duty ratio. Theduty ratio is the time period in which the switch is “on” divided by thetime period of the switching cycle (e.g., in accordance with theequation D=Ton/Tp). The switching cycle time period is typically equalto the time period in which the switch is “on” plus the time period inwhich the switch is “off” and plus any time period in which the switchis “idle” (where Tp=Ton+Toff+Tidle). The output voltage of the buckconverter in CCM (continuous conduction mode) is theoretically equal tothe input voltage multiplied by the duty ratio (e.g., in accordance withthe equation: Vout=Vin*D). The ranges of values of Ton and Toff aretypically selected during design time (e.g., to achieve an optimumefficiency from a given technology process node in order to meet maskspecifications of wireless standards, and the like).

The disclosed power supply 110 includes a fast mode-transitioning powerconverter 138, which in turn includes an auxiliary voltage output stage.The fast mode-transitioning power converter is operable to provide arelatively low-power PWM mode of operation (“auxiliary PWM”) for a PApower converter, having very low quiescent (no-load) currents, and whichcan be operated in parallel to the PFM mode. The auxiliary PWM mode canbe introduced whenever the converter needs to provide a very low loadcurrent, and is operable to provide a rapid transition to the PWM modeof operation to meet application system demands. Accordingly, the fastmode-transitioning power converter provides a rapid settling time (e.g.,which is often required by WLAN standards) while allowing the powerconverter to operate as much as possible in PFM mode (e.g., which helpsminimize power consumption by the power converter).

In one example, the power supply 110 is a DC-DC converter operable tooperate in a discontinuous conduction mode (DCM). As introduced above,the power supply 110 includes a fast mode-transitioning power converter138. Although the fast mode-transitioning power converter 138 isillustrated as being included in the power supply 110 or as a single(e.g., logical) unit, various portions of the fast mode-transitioningpower converter 138 are optionally included in the same module (e.g., asformed by a die as produced in semiconductor manufacturing) or indifferent modules.

The fast mode-transitioning power converter 138 is operable to provide arelatively low-power PWM mode of operation (“auxiliary PWM”). Theauxiliary PWM mode is typically operated in parallel to (e.g., at thesame time as operating in) operation of a PFM mode. The fastmode-transitioning power converter 138 is operable to provide rapidtransitions between PFM and PWM modes. In various embodiments, the fastmode-transitioning power converter 138 is a buck converter, a buck-boostconverter, or the like. In example embodiments, the fastmode-transitioning power converter 138 comprises an auxiliary voltageoutput stage (e.g., 270 of FIG. 2) that includes power switches (such asFET switches) and passive components selected in accordance with atarget application.

FIG. 2 is a schematic diagram illustrating a fast mode-transitioningpower converter 200 in accordance with example embodiments of thedisclosure. The fast mode-transitioning power converter 200 includes aparticular embodiment of the fast mode-transitioning power converter 138of FIG. 1, and is optionally formed (e.g., in whole or in part) on asubstrate 202. Generally described, the fast mode-transitioning powerconverter 200 includes a mode signal generator 210, a mode controller220, a sensor 228, a PFM controller 240, a PWM controller 250, a poweroutput stage 260 (e.g., operable to generate a voltage output Vout), andan auxiliary voltage output stage 270 (e.g., operable to generate anauxiliary output voltage Vaux).

The mode signal generator 210 generates signals that are operable toselect operation in a PFM mode or in a PWM mode voltage output. The modesignal generator can be operated in response to signals from a processorsuch as a CPU 112 (as illustrated in FIG. 1). In various embodiments,the processor sends signals to the mode signal generator 210 in responseto communications network protocols, such as network interface protocolsthat determine whether the electronic system 129 is in a receiving modeor a transmitting mode. For example, the mode signal generator 210selects operating modes of the fast mode-transitioning power converter200 in response to a selected transmission/receive mode of atransceiver. Accordingly, the fast mode-transitioning power converter200 is operable to supply operating power in accordance with standardsassociated with a particular operating mode.

The mode signal generator 210 is coupled to the mode controller 220. Themode controller 220 is (for example) operable to control timing oftransitions and to buffer control signals. The optional current sensor230 is operable to measure an operating load current. The mode signalgenerator 210 is optionally responsive to the sensor 228 (e.g., operableto select an operating mode in response to an operating current load).The sensor 228 includes a current sensor 230 and a zero crossingdetector 232, both of which provide control information used to controlswitches of the power output stage 260, for example.

More particularly, the PFM controller 240 comprises a PFM controller245, a switch 247, and a logic unit 249, which drives the power stage260. In the PFM controller 240, the PFM controller 245 is coupled to avoltage reference Vref and the voltage output Vout, and to the switch247 which controls the connection of the PFM controller 245 to the logicunit 249 that drives the power stage 260. The PWM controller 255 iscoupled to a voltage reference Vref and to the switch 251, whichcontrols the connection of the PWM controller 255 to the voltage outputVout. The mode controller 220 is coupled to the switch 247 of the PFMcontroller 240. For example, when the fast mode-transitioning powerconverter 200 is operating in a PFM mode, the switch 247 is operable toselectively couple the output of the PFM controller 245 to the input ofthe logic unit 249.

Similarly, the PWM controller 250 comprises a switch 251, a switch 253,a PWM controller 255, a switch 257, a switch 258, and a logic unit 259that drives the auxiliary power stage 270. The PWM controller 255 isalso coupled to the switch 253, which controls the connection of the PWMcontroller 255 to the auxiliary output voltage Vaux. The PWM controller255 is also coupled to the switch 257, which controls the connection ofthe PWM controller 255 to the logic unit 249 of the PFM controller 240.The PWM controller 255 is also coupled to the switch 258, which controlsthe connection of the PWM controller 255 to the logic unit 259. The modecontroller 220 is coupled to the switches 251, 253, 257, and 258 of thePWM controller 250.

For example, the switch 251 is operable to selectively couple thevoltage output Vout to an input of the PWM controller 255 when the fastmode-transitioning power converter 200 is operating in a PWM mode. Theswitch 257 is operable to selectively couple the output of the PWMcontroller 255 to the input of the logic unit 249 that drives the powerstage 260. To increase the speed of transitioning to the PWM mode, theswitch 258 is operable to selectively couple the output of the PWMcontroller 255 to the input of the logic unit 259 (which in turnactivates the auxiliary voltage source 270) before entering the PWMmode. The switch 253 is closed (while the switch 251 is open), whichcouples the Vaux signal (generated by the auxiliary voltage generator270) to the input of the PWM controller 255. Coupling the Vaux signal tothe PWM controller before entering the PWM mode (e.g., while operatingin a quiescent mode or a PFM mode) initiates stabilization of the PWMcontroller 250 control loop without (for example) substantiallyinterrupting the existing operating mode of the fast mode-transitioningpower converter 250.

The power output stage 260 includes a power FET switch 265. The powerFET switch 265 is operable to selectively couple a voltage source to afirst terminal an energy storage element such as inductor L. A secondterminal of the inductor L is coupled to the high side of capacitor Cand to the output voltage node Vout. A load is optionally coupled to thenode Vout and optionally comprises the current sensor 230. The powerswitch 265 is driven in response to outputs of the logic unit 249.

The auxiliary voltage output stage 270 includes a FET switch 275. Thepower FET switch 275 is operable to selectively couple a voltage sourceto an input terminal of a network that is operable to emulate thefrequency response of passive components present in the output powerstage 260. For example, the ‘LC’ frequency response is emulated whencontrolling a buck converter. The passive network includes a firstresistor R1 and a second resistor R2. A first capacitor C1 is coupledbetween a center node of the resistor network (e.g., between R1 and R2)and ground. A second capacitor C2 is coupled between an output terminalof the resistor network and ground. The output terminal of C2 providesthe auxiliary voltage output Vaux. The components R1, R2, C1, and C2 areformed (for example) on the same substrate as the PWM controller 250(and the PFM controller 240) and are selected such that the loop of thePWM controller 250 that includes the feedback signal Vaux is stable. Thepower switch 275 is driven in response to outputs of the logic unit 259of the PWM controller 250 such that the supply voltage is converted toVaux. When not in use, the power switch 275 is optionally placed in anopen state such that the supply voltage is not coupled to the centernode of the voltage divider and, accordingly, power consumption isreduced.

In operation, the mode signal generator 210 and the optional currentsensor 230 provide input signals to the mode controller 220, whichactuates (e.g., opens and closes) the switches of the PFM controller 240and the PWM controller 250 in response to the input signals. To operatein a PFM mode (PFM-only mode, for example), the mode controller 220signals the switch 247 of the PFM controller 240 to close (e.g., whileother switches of the PWM controller 250 remain open). Accordingly, thelogic unit 249 of the PFM controller 240 is operable to control theoutput voltage Vout in response to PFM mode signals generated by the PFMcontroller 245.

To facilitate a fast transition from operating in the PFM mode to thePWM mode, an auxiliary PWM mode is disclosed in which a PWM mode isoperated in parallel with PFM mode. To enter the auxiliary PWM mode, themode controller 220 signals the switches 253 and 258 of the PWMcontroller 250 to close. When the switches 253 and 258 are closed (andthe switch 251 and 257 are open), the PWM controller 255 is arranged tocompare the auxiliary voltage Vaux with (e.g., against) the voltage ofVref and, in response, generates control signals for regulating theauxiliary voltage Vaux (which is output by the auxiliary voltage outputstage 270). Operating in the auxiliary PWM mode (in which the auxiliaryvoltage output stage 270 is operating) consumes substantially less powerthan the power output stage 260 would otherwise consume when continuingto operate in the PWM mode of operation. The reduction in powerconsumption results in, for example, increased operating times inrestricted-power consumption applications (e.g., such as when operatingfrom battery power).

To transition from operating in the PFM mode to operating in a (e.g.,standard) PWM mode, the mode controller 220 signals the switches 251 and257 of the PWM controller 250 to close (and switch 253 and 258 areopened). The voltage of Vaux is typically selected to be the samevoltage as the nominal voltage of Vout such that the operating points ofthe PWM controller 250 settle to same values in both the cases: (a) whenswitches 253 and 258 are closed and switches 251 and 257 are open; and(b) when switches 253 and 258 are open and switches 251 and 257 areclosed. The operating points in the just mentioned cases may differslightly due to mismatch in the formation of on-chip components. Havingsimilar operating points, for example, facilitates fast transitioningbetween operating modes. When the switches 251 and 257 are closed, thePWM controller 255 is arranged to compare the output voltage Voutagainst the voltage of Vref and, in response, generates control signalsfor regulating the output voltage Vout.

When the mode controller 220 causes switches 251 and 257 of the PWMcontroller 250 to close, the mode controller 220 opens the switch 247(e.g., sometime shortly thereafter) of the PFM controller 240, whichtransfers the control of the power output stage 260 to PWM controller250. After the PFM-to-PWM transition is complete, the auxiliary PWM modeis (e.g., optionally) disengaged by the mode controller 220 signalingthe switches 253 and 258 to open (and the auxiliary voltage source 270shut down). When the input to the mode controller 220 from the modesignal generator 210 indicates that the fast mode-transitioning powerconverter 200 is to transition from operating in a PWM mode back tooperating in a PFM mode, the mode controller 220 signals the switch 247to close, and (e.g., at approximately the same time) signals theswitches 251 and 257 to open.

FIG. 3 is a waveform diagram illustrating switching waveforms and outputvoltages of a fast mode-transitioning power converter in accordance withexample embodiments of the disclosure. Generally described, waveformdiagram 300 illustrates changes in voltages and state over time ofvarious signals of a fast mode-transitioning power converter. Waveformdiagram 300 includes an enable PFM signal (EN_PFM) 320, an enable PWMsignal (EN_PWM) 310, an enable auxiliary PWM signal (EN_AUXILIARY_PWM)330, an output voltage (Vout) 340, and an auxiliary voltage (Vaux) 350.The enable signals EN_PFM 320, EN_PWM 310, and EN_AUXILIARY_PWM 330represent digital signals such as those generated by the mode signalgenerator 210 of the fast mode-transitioning power converter 200illustrated in FIG. 2.

A low voltage for each of EN_PFM 320, EN_PWM 310, and EN_AUXILIARY_PWM330 represents an “off” state, and a high voltage represents an “on”state. Vertical lines in the waveform diagram 300 demarcate particularperiods of time, which occur during operation of the fastmode-transitioning power converter 138 and/or the fastmode-transitioning power converter 200.

The output voltage (Vout) 340 and the auxiliary voltage (Vaux) 350represent the magnitude of these voltages over time as produced by thepower output stage 260 and the auxiliary voltage output stage 270,respectively, illustrated in FIG. 2. The power output stage 260 isenabled by a positive transition of EN_PFM 320 such that the poweroutput stage 260 begins to generate an output voltage (Vout). Vout 340rises during an initial portion of the PFM mode 362 and fluctuatesbetween a lower threshold voltage and a higher threshold voltage whenregulation is achieved by the PFM controller 240 during a later portionof PFM mode 362.

In anticipation of entering a PWM mode (such as determined by atransceiver controller, for example), the EN-AUXILIARY-PWM 330 isasserted and the auxiliary PWM mode (e.g., AUX-PWM period 382) isentered. When the EN-AUXILIARY-PWM 330 is asserted, Vaux 350 rises to avoltage that is approximately equal to the target voltage of Vout 340.Regulation is achieved by PWM controller 250 when Vaux 350 rises to theapproximately equal target voltage.

After regulation is achieved by PWM controller 250 (or after asufficient length of time, for example) during the auxiliary PWM mode,EN_PFM 320 is deasserted (e.g., negated) and EN_PWM 310 is asserted. At(e.g., around) this time, the PWM controller 250 (using Vaux 350 as areference) is used to regulate the power output stage 260. Accordingly,the operation (e.g., achieving feedback stability) of the PWM controller250 is bootstrapped without, for example, being (e.g., yet) coupled toregulate the voltage Vout 340.

The PWM mode (e.g., PWM period 372) is entered (and the auxiliary PWMmode exited) around the time when the EN_AUXILIARY_PWM 330 is deassertedWhen the EN_AUXILIARY_PWM 330 is deasserted, the PWM controller 250regulates the power output stage 260 using the (e.g., selectivelycoupled) Vout 340 as a reference. In an embodiment, the signal Vaux 350is decoupled from an input of the PWM controller 255 at this time suchthat the auxiliary voltage output stage 270 is no longer regulated, andaccordingly Vaux 350 begins to drop.

In anticipation of exiting a PWM mode (such as determined by atransceiver controller, for example), the EN_PWM 310 is deasserted andthe PFM mode (e.g., PFM period 364) is entered. When the EN_PWM 310 isdeasserted, EN_PFM 320 is asserted such that the PFM mode is entered asdescribed above. Signal EN_AUXILIARY_PWM is optionally asserted at thistime or asserted after time Tflex (time flex) 396 (e.g., to reduce powerconsumption over time Tflex 396). Regulation is achieved by PFMcontroller 240 when Vout 340 fluctuates between two threshold voltages.

In anticipation of entering the next PWM mode, an auxiliary PWM mode isused to bootstrap the PWM controller 259 as described above. Turning thePWM controller off when not (e.g., necessarily) needed (such as during aPFM mode) saves power, but requires additional time to bootstrap the PWMcontroller 250 when reactivating the PWM controller 250. Accordingly,using the auxiliary PWM mode to bootstrap the PWM controller 250 reducesthe amount of time otherwise required to bootstrap the PWM controller250 and reduces overall power consumption of the system by providingfast mode transitions.

Accordingly, PFM time periods 362, 364, and 366 are periods when theenable signal EN_PFM 320 is on such that the fast mode-transitioningpower converter 138 is operating in a PFM mode. PWM time periods 372 and374 are periods when the enable signal EN_PWM 310 is enabled and thefast mode-transitioning power converter 138 is operating in a PWM mode.AUX_PWM time periods 382, 384, and 386 are periods when the enablesignal EN_AUXILIARY_PWM 330 is enabled and the fast mode-transitioningpower converter 138 is operating in an auxiliary PWM mode, often at thesame time that the fast mode-transitioning power converter 138 isoperating in PFM mode.

Accordingly, the auxiliary voltage Vaux 350 provided by the auxiliaryvoltage output stage 270 (illustrated in FIG. 2) is operable to providerapid power settling of Vout 340 during the transition from operation ofthe fast mode-transitioning power converter 138 in a PFM mode tooperation in a PWM mode.

The Tflex (flexible time) time period 396 is a time period in which theenable signal EN_AUXILIARY_PWM 330 optionally remains off for a longertime (e.g., as shown by the portion 334 of EN_AUXILIARY_PWM 330) afterthe assertion on EN-PFM 320 in the first portion of PFM 364. The portion354 of the auxiliary voltage (Vaux) waveform represents the lower levelof auxiliary voltage (Vaux) that is achieved by the auxiliary voltageoutput stage 270 (illustrated in FIG. 2) when the enable signalEN_AUXILIARY_PWM optionally remains off for the time period 396.

FIG. 4 is a waveform simulation illustrating switching waveforms, outputvoltages, and currents of a fast mode-transitioning power converter inaccordance with example embodiments of the disclosure. Generallydescribed, waveform diagram 400 illustrates waveforms of an enable PFMsignal (EN_PFM) 410, an enable PWM signal (EN_PWM) 420, an enableauxiliary PWM signal (EN_AUXILIARY_PWM) 430, an output voltage (Vout)440, an auxiliary voltage (Vaux) 450, a load current 460, an inductorcurrent 470, and a supply current 480.

Waveform diagram 400 illustrates simulation results of the outputvoltages and measurements of the internal current of the fastmode-transitioning power converter 138 in response to a transition fromoperation in the PFM mode to the PWM mode. The (EN_AUXILIARY_PWM) 430signal represents the operation the Vaux 450 regulation control signalduring the auxiliary PWM mode. Initially, the enable PFM signal (EN_PFM)410 is asserted at the start of the simulation. At a time correspondingto approximately 500.0 microseconds, the enable PWM signal (EN_PWM) 420is asserted. At approximately 504.0 microseconds (“the PFM-to-PWMtransition time point”), the enable PFM signal (EN_PFM) 410 isdeasserted such that the fast mode-transitioning power convertertransitions from PFM mode to PWM mode. At the PFM-to-PWM transition timepoint, a momentary lack of regulation (e.g., by using Vout, rather thanVaux, as the feedback signal) causes spikes in both the output voltage(Vout) 440 and the auxiliary voltage (Vaux) 450. The extent of thespikes reduces as the feedback loop stabilizes and the now-regulatedvoltages both settle into a consistent PWM mode pattern (e.g., in arelatively short period of time) at approximately 511.0 microseconds.The output voltage (Vout) 440 is regulated (e.g., by using Vout as thefeedback signal) to maintain a voltage around 1.8 volts fromapproximately 511.0 microseconds onwards (over which time the auxiliaryvoltage Vaux 450 rises, for example, due to lack of regulation whilestill being switched).

Similarly, the inductor current 470 (for example, as present in inductorL of the power output stage 260 illustrated in FIG. 2) starts flowing atthe PFM-to-PWM transition time point and settles into a consistent PWMmode pattern by approximately 511.0 microseconds (e.g., even with theincrease in the load current 460 that occurs at approximately 510.0microseconds).

The supply current 480 is sourced by the inductor current 470. A smallspike in the supply current 480 occurs at the PFM-to-PWM transition timepoint and settles by approximately 511.0 microseconds. Accordingly, thepresence of the auxiliary voltage (Vaux) 450, as produced by theauxiliary voltage output stage 270 for example, in response to theenable auxiliary PWM signal (EN_AUXILIARY_PWM) 430, allows the fastmode-transitioning power converter 138 to rapidly transition from PFMmode to PWM mode with power settling occurring within approximately 7microseconds. Accordingly, the output voltage of the output voltagestage is regulated within a time that is less than around 8 microsecondsafter the start of the second period of time (e.g., wherein the outputvoltage is regulated at a variance that is around less than 1 percent inthe power generated by the power output stage).

FIG. 5 is a flow diagram illustrating a method of operation of a powerconverter with an auxiliary voltage output stage in accordance withexample embodiments of the disclosure. Program flow 500 begins inoperation 510, in which the power converter with an auxiliary voltageoutput stage begins operating in a PFM mode. Program flow continues tooperation 512.

In operation 512, the auxiliary voltage output stage of a powerconverter (optionally) begins operating in preparation for a potentialtransition to PWM mode. Such preparation includes applying power tounpowered portions of circuitry in the auxiliary voltage output stage.In various embodiments (e.g., such as in applications where the rate ofpower consumption is not currently a limiting factor), the auxiliaryvoltage output stage of a power converter remains powered up in a “warm”state. During the warm state, not all power is removed from theauxiliary voltage output stage (e.g., which reduces latency whenswitching between the PFM and the PWM modes. Program flow proceeds tooperation 514.

In operation 514, the mode controller of the auxiliary voltage outputstage receives signals from the mode signal generator. The signal modegenerator generates signals for transitioning to the auxiliary PWM(AUX_PWM) mode. The signals are generated in response to signals from aprocessor, for example, which provide an indication of an operation mode(e.g., send or receive) of an electronic communications system. Thesignals from the processor optionally are generated in response tohistorical transmission patterns (send and receive modes over timerepresented in data stored in a database, for example) and/or generatedin response to the expiration of predetermined timer values. Programflow continues to operation 516.

In operation 516, the mode controller of the power converter with anauxiliary voltage output stage determines whether a signal forcontinuing operation has been received. If so, program flow continues tooperation 520. If not, program flow terminates. Program flow isoptionally reinitiated with commencement of program flow at operation510.

In operation 520, the mode controller of the power converter with anauxiliary voltage output stage determines whether a signal for enablingoperation in PWM mode has been received. If so, program flow continuesto operation 522. If not, program flow waits (or e.g., restarts byproceeding to operation 510).

In operation 522, the mode controller of the power converter with anauxiliary voltage output stage determines whether the auxiliary PWM(AUX_PWM) mode is in operation. If so, program flow continues tooperation 530. If not, program flow proceeds to operation 524.

In operation 524, the power converter with an auxiliary voltage outputstage begins operating in auxiliary PWM (AUX_PWM) mode (which, forexample, reduces latency of initializing the PWM controller bystabilizing the feedback loop of the PWM controller before the PWM modeis entered. Program flow continues to operation 530.

In operation 530, the power converter with an auxiliary voltage outputstage begins operating in PWM mode, and at the same time or shortlythereafter, the power converter with an auxiliary voltage output stageceases operating in PFM mode. Program flow continues to operation 532.

In operation 532, the power converter with an auxiliary voltage outputstage optionally ceases operating in auxiliary PWM (AUX_PWM) mode inresponse to signals from a processor. Ceasing operation of the auxiliaryPWM mode, for example, saves power otherwise used to power componentsused in the AUX_PWM mode. Program flow proceeds to operation 534.

In operation 534, the mode controller of the power converter with anauxiliary voltage output stage receives signals from the mode signalgenerator. Program flow continues to operation 536.

In operation 536, the mode controller of the power converter with anauxiliary voltage output stage determines whether a signal forcontinuing operation has been received. If so, program flow continues tooperation 538. If not, program flow terminates. Program flow mayoptionally be reinitiated (e.g., restarted) with recommencement ofprogram flow at operation 510.

In operation 538, the mode controller of the power converter with anauxiliary voltage output stage determines whether a signal enabling foroperation in PFM mode has been received. If so, program flow continuesto operation 540. If not, program flow proceeds to operation 534.

In operation 540, the power converter with an auxiliary voltage outputstage begins operating in PFM mode, and at the same time or shortlythereafter, the power converter with an auxiliary voltage output stageceases operating in PWM mode. Program flow continues to operation 512.

In various embodiments, the above-described components can beimplemented in hardware or software, internally or externally, and sharefunctionality with other modules and components as illustrated herein.

The various embodiments described above are provided by way ofillustration only and should not be construed to limit the claimsattached hereto. Those skilled in the art will readily recognize variousmodifications and changes that could be made without following theexample embodiments and applications illustrated and described herein,and without departing from the true spirit and scope of the followingclaims.

What is claimed is:
 1. A circuit device comprising: a first power stagethat includes: a first voltage source input; an energy storage element;a first switch coupled between the first voltage source input and theenergy storage element; and a first voltage output coupled to the energystorage element; a first controller that includes: a first set ofcontroller logic coupled to the first switch; and a first controllerunit that includes an input coupled to the first voltage output and anoutput coupled to the first set of controller logic; and a second powerstage that includes: a second voltage source input; a second voltageoutput; and a second switch coupled between the second voltage sourceinput and the second voltage output; a second controller that includes:a second set of controller logic coupled to the second switch; and asecond controller unit that includes: an input coupled to the firstvoltage output and the second voltage output; and an output coupled tothe first set of controller logic and the second set of controllerlogic.
 2. The circuit device of claim 1, wherein: the second power stageincludes: a third switch coupled between the first voltage output andthe input of the second controller unit; and a fourth switch coupledbetween the second voltage output and the input of the second controllerunit; and the circuit device includes a mode controller coupled tocontrol the third switch and the fourth switch.
 3. The circuit device ofclaim 2, wherein: the second power stage includes: a fifth switchcoupled between the output of the second controller unit and the firstset of controller logic; and a sixth switch coupled between the outputof the second controller unit and the second set of controller logic;and the mode controller is coupled to control the fifth switch and thesixth switch.
 4. The circuit device of claim 3, wherein: the first powerstage includes a seventh switch coupled between the output of the firstcontroller unit and the first set of controller logic; and the modecontroller is coupled to control the seventh switch.
 5. The circuitdevice of claim 1 further comprising a mode controller coupled to thefirst controller and the second controller and configured to: during afirst period of time, cause the first controller unit to drive the firstset of controller logic to control a voltage at the first voltageoutput; during a second period of time that overlaps with a portion ofthe first period of time, cause the second controller unit to drive thesecond set of controller logic to control a voltage at the secondvoltage output; and during a third period of time that follows thesecond period of time, cause the second controller unit to drive thefirst set of controller logic to control the voltage at the firstvoltage output.
 6. The circuit device of claim 5, wherein the thirdperiod of time immediately follows the second period of time.
 7. Thecircuit device of claim 5, wherein the second period of time beginsafter a beginning of the first period of time.
 8. The circuit device ofclaim 5, wherein: during the second period of time, the voltage at thesecond voltage output rises to a steady state; and the mode controlleris configured to transition from the second period of time to the thirdperiod of time after the voltage at the second voltage output has risento the steady state.
 9. The circuit device of claim 5, wherein, during aportion of the first period of time that does not overlap with thesecond period of time, the voltage at the second voltage output falls.10. The circuit device of claim 5 further comprising a transmitter,wherein the mode controller is configured to begin the third period oftime in response to a transmit mode of the transmitter.
 11. The circuitdevice of claim 1, wherein the second power stage includes: a set ofresistors coupled in series between the second switch and the secondvoltage output; and a set of capacitors each coupled between the set ofresistors and a ground node.
 12. The circuit device of claim 1, wherein:the first controller unit is a pulse frequency modulation controllerunit; and the second controller unit is a pulse width modulationcontroller unit.
 13. A circuit device comprising: a first power stagethat includes: an energy storage element; a first switch coupled betweena first voltage source and the energy storage element; a second switchcoupled between a ground node and the energy storage element; and afirst voltage output coupled to the energy storage element; a firstcontroller that includes: a first set of controller logic coupled to thefirst switch and the second switch; and a first controller unit thatincludes an input coupled to the first voltage output and an outputcoupled to the first set of controller logic; and a second power stagethat includes: a third switch coupled between a second voltage sourceand a node; a fourth switch coupled between the ground node and thenode; and a second voltage output coupled to the node; and a secondcontroller that includes: a second set of controller logic coupled tothe third switch and the fourth switch; and a second controller unitthat includes: an input coupled to the first voltage output and thesecond voltage output; and an output coupled to the first set ofcontroller logic and the second set of controller logic.
 14. The circuitdevice of claim 13, wherein: the second power stage includes: a fifthswitch coupled between the first voltage output and the input of thesecond controller unit; and a sixth switch coupled between the secondvoltage output and the input of the second controller unit; and thecircuit device includes a mode controller coupled to control the fifthswitch and the sixth switch.
 15. The circuit device of claim 14,wherein: the second power stage includes: a seventh switch coupledbetween the output of the second controller unit and the first set ofcontroller logic; and an eighth switch coupled between the output of thesecond controller unit and the second set of controller logic; and themode controller is coupled to control the seventh switch and the eighthswitch.
 16. The circuit device of claim 15, wherein: the first powerstage includes a ninth switch coupled between the output of the firstcontroller unit and the first set of controller logic; and the modecontroller is coupled to control the ninth switch.
 17. The circuitdevice of claim 13 further comprising a mode controller coupled to thefirst controller and the second controller and configured to: during afirst period of time, cause the first controller unit to drive the firstset of controller logic to control a voltage at the first voltageoutput; during a second period of time that overlaps with a portion ofthe first period of time, cause the second controller unit to drive thesecond set of controller logic to control a voltage at the secondvoltage output; and during a third period of time that follows thesecond period of time, cause the second controller unit to drive thefirst set of controller logic to control the voltage at the firstvoltage output.
 18. The circuit device of claim 17 further comprising atransmitter, wherein the mode controller is configured to begin thethird period of time in response to a transmit mode of the transmitter.19. The circuit device of claim 13, wherein the second power stageincludes: a set of resistors coupled in series between the node and thesecond voltage output; and a set of capacitors each coupled between theset of resistors and the ground node.
 20. The circuit device of claim13, wherein: the first controller unit is a pulse frequency modulationcontroller unit; and the second controller unit is a pulse widthmodulation controller unit.